Transient Tachypnea of the Newborn Clinical Trial
Official title:
A Randomized Controlled Trial of Fluid Management in Transient Tachypnea of the Newborn
Transient tachypnea of the newborn (TTN) is a diagnosis given to infants born between 34 and
42 weeks gestation who develop difficulty breathing during the first days of life when no
specific cause of the breathing difficulty can be identified. Little is known about why some
babies develop TTN, and there have not been many formal studies of the best way to take care
of babies with this disease. Babies with TTN get better on their own within three to five
days after birth, but may require extra oxygen to breath well.
Most physicians believe that the symptoms of TTN are related to poor clearance of fluid from
the newborn's lungs. Babies with TTN have extra fluid visible on chest x-ray. Diuretics,
medicines that can help clear extra lung fluid in adults and in babies with extra lung fluid
for other reasons, do not to help babies with TTN. Babies with TTN need intravenous fluids
to be healthy because they breathe too fast to be able to eat. Breastfed babies only get a
very small amount of fluid in the first few days of life, as it normally takes several days
for a new mother to begin producing breastmilk. No one has yet examined whether giving
babies with TTN an amount of fluid similar to the small amount they would receive if they
could breastfeed would help them recover from TTN faster.
In this study, the investigators compare whether giving newborns "standard" intravenous
fluid or amounts of intravenous fluid more close to what a breastfed baby would receive
speeds recovery in newborns with TTN.
1. Project Abstract Transient tachypnea of the newborn (TTN) is a self-limited respiratory
distress syndrome of term and late pre-term neonates.1 Respiratory distress attributed
to TTN requires management of otherwise healthy infants in an intensive care setting,
thus increasing cost, and often length, of hospitalization as well as decreasing
opportunity for parent-child bonding in the first days of life. Although hundreds of
thousands of children are treated for TTN every year (over 250 in the Mount Sinai NICU
in 2005 alone), little data underlie standard of care medical management. We are
conducting a prospective study of neonates diagnosed with TTN to determine if changes
in fluid management affects course of disease.
2. Specific Aims To determine whether fluid restriction in the first 72 hours of life
speeds resolution of respiratory distress in neonates diagnosed with TTN.
3. Concise statement of Significance/Background Transient tachypnea of the newborn (TTN)
is a self-limited respiratory distress syndrome of term and late pre-term neonates.1
Newborns with TTN develop clinical signs of respiratory distress within the first hours
after birth, in the absence of other pathology such as surfactant deficiency,
infection, meconium aspiration, or anatomic cardiac or pulmonary anomaly. Signs of TTN
include tachypnea (respiratory rate consistently > 60), subcostal, intercostals, and
suprasternal retractions, nasal flaring, grunting, and hypoxia correctable with low
FiO2 supplemental oxygen (< 0.40) via conventional nasal cannula or continuous positive
airway pressure (CPAP). The condition usually resolves with supportive care within 72
hours without significant long-term adverse sequelae. Transient tachypnea of the
newborn is associated with transient pulmonary edema diagnosed by typical chest x-ray
findings.
The traditional explanation for postnatal pulmonary edema is poor clearance of fluid
from the fetal lungs in the perinatal period. Retained fluid leads to bronchioalveolar
collapse with variable areas of hyperinflation and air trapping in the neonatal lung.
The newborn compensates for this ventilation/perfusion mismatch with tachypnea and
increased work of breathing, but often cannot completely compensate, becoming hypoxic
through the period of fluid reabsorption.
This pathophysiologic argument has been supported by the findings that brief or absent
labor and short or absent time in the birth canal have been associated with TTN.2, 3 It
has long been hypothesized that mechanical forces of labor and delivery work to
"squeeze" edema away from air-exchange surfaces of the lung into the lymphatics. More
recently, studies have demonstrated that immaturity of sodium ion channel transporters
in the lung epithelium may play a more significant role in the failure of pulmonary
fluid reabsorption than mechanical forces.4, 5 Data from animal models show that absent
labor, such as found in scheduled Cesarean sections, may lead to delivery before the
normal hormonally-mediated upregulation or activation of these sodium transporters
occurs and thus may explain the increased likelihood of developing TTN seen in this
patient cohort.
Conditions that increase central venous pressure or decrease thoracic duct clearance
have also been associated with TTN.6 Additionally, maternal diagnosis of asthma7 or
gestational diabetes8 and male gender of the newborn9 have been associated with TTN,
although the mechanism of these associations is incompletely understood. Although TTN
is an exceedingly common cause of newborn morbidity, it is relatively understudied. Due
to the low mortality of TTN there has been little interest in investigating either the
range of pathologies underlying the clinical presentation of TTN or the evidence base
behind the standard of care treatments of TTN. The high incidence of TTN and the
significant increase in hospital care acuity and length of stay to otherwise healthy
infants diagnosed with TTN, however, indicates a need for study.10 As the rate of
Cesarean section and late pre-term delivery,11 as well as maternal morbidities such as
asthma12 and gestational diabetes,13 rise it is particularly important to minimize the
morbidity and cost of TTN. A better understanding of the pathogenesis of TTN and a
thorough evaluation of current treatment strategies and their relationship to timely
patient discharge is sorely needed.
4. Concise statement of Preliminary Data (if available) No evidence base underlies current
fluid management of neonates with TTN. Data exists demonstrating the inefficacy of loop
diuretics as treatment for pulmonary fluid overload in newborns with TTN,14 but no
systematic evaluation of intravenous fluid management exists. Exclusively breastfed
babies typically have minimal fluid intake during the first four days of life as
lactogenesis II (initial postpartum milk production) proceeds. Enteral intake by term
infants begins at less than 100mL in the first day (equivalent to 40mL/kg for a 2.5kg
neonate; this represents a term newborn at the 5th percentile or a 34 week gestational
age newborn at the 70th percentile for weight) and increase gradually until milk
production reaches sustenance levels, usually around the fourth day of life.15
Regardless of gestational age, all neonates lose water weight during the first week of
life during physiologic diuresis of extracellular fluid accumulated throughout
gestation.16 Current management of both preterm and term neonates includes an effort to
facilitate this physiologic diuresis by gradually increasing amounts of IV fluids until
maintenance levels are reached between the third and fifth day of life. 17, 18
5. Research Design and Methods In this study, we will conduct a prospective study of 68
neonates born between 34 and 42 weeks gestation diagnosed with TTN and managed in the
Mount Sinai Neonatal Intensive Care Unit (NICU). The study period will include the
first three days (72 hours) of life. On admission to the NICU, parents will be
consented for their child's inclusion in the study. If consent is given, the child will
be randomized to "standard fluids" or "physiologic fluids" groups. "Standard fluids"
refer to current standard clinical practice of IV fluid administration, not based on
experimental evidence. "Physiologic fluids" refers to IV fluid amounts more similar to
fluid volumes typically ingested during initiation of breastfeeding. Term infants
assigned to the "standard fluids" group will be started on 60 mL/kg/day of
glucose-containing intravenous fluids as is standard practice. Term infants assigned to
the "physiologic fluids" group will be started on 40 mL/kg/day glucose-containing
intravenous fluids. Late preterm infants (gestational age between 34 and 37 weeks)
assigned to the "standard fluids" group will be started on 80 mL/kg/day of
glucose-containing intravenous fluids as is standard practice. Late preterm infants
(gestational age between 34 and 37 weeks) assigned to the "physiologic fluids" group
will be started on 60 mL/kg/day glucose-containing intravenous fluids. For all groups,
intravenous fluid rate will be increased by 20 mL/kg/day daily, as is current standard
practice. Consistent with current standard management for newborns with respiratory
distress, no infant will be allowed to take oral nutrition until respiratory distress
abates. Newborns will be carefully monitored, and infants in the "physiologic fluid"
group will be removed from the study and total daily fluids will be increased if they
show signs of dehydration. Primary outcomes will be duration of respiratory distress,
defined as respiratory rate consistently greater than 50 breaths/minute and oxygen
saturation on room air consistently less than 95%. Secondary outcomes will be length of
time to first oral feed and time to discharge from the intensive care unit.
This research poses a minor increase over minimal risk for subjects enrolled in the
intervention group. The anticipated risks include mild dehydration and/or hypoglycemia of
neonates in the "physiologic fluid" intervention group. This risk is minor as all newborns
in the NICU have urine output recorded every three hours, point-of-care glucose monitoring
on admission and at least once every twelve hours thereafter, and serum electrolytes checked
between 12 and 24 hours of life. If neonatal dehydration is noted as defined by urine output
< 2mL/kg/hour over a twelve hour period, serum sodium < 130 mEq/L or > 150 mEq/L, weight
loss of more than 10% of birth weight, or blood glucose by point-of-care testing of < 40
mg/dL, the child will be removed from the study and appropriate fluid resuscitation will be
initiated. These guidelines for removal from the study are the same as or more conservative
than criteria used for rehydration in clinical care, so long-term adverse sequelae of this
level of brief mild dehydration or hypoglycemia are not expected.
;
Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Parallel Assignment, Masking: Open Label, Primary Purpose: Treatment
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